System, method, and apparatus for certifying a brake pressure calibration for an end-of-train device

ABSTRACT

A system, method, and apparatus for certifying an end-of-train device pressure calibration is provided. The system includes a pressure calibration device configured to output a regulated pressure; and an end-of-train device comprising: a brake pipe interface adapted to receive the regulated pressure from the pressure calibration device; and a pressure sensing device configured to obtain a measured pressure by measuring the regulated pressure. At least one of the pressure calibration device and the end-of-train device comprises at least one controller configured to determine a calibration certification result based at least partially on a difference between the measured pressure and the regulated pressure.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to brake pressure calibration and, inparticular, a system, method, and apparatus for certifying a brakepressure calibration of an end-of-train device.

2. Description of Related Art

Typically, end-of-train (EOT) devices are required to report the brakepipe pressure of a train within a specified accuracy. The accuracy ofthe pressure transducer or other sensing device in an EOT device may bemandated by a government agency or entity such as the Federal RailroadAdministration (FRA). Under FRA regulations, the accuracy of EOT devicepressure measurements must be verified annually.

Traditionally, determining the accuracy of an EOT device pressuretransducer is a manual process that is part of an FRA annual inspection.The inspection occurs on-site and requires the presence of FRA agents.The manual nature of such testing and inspection allows for operator orinspector error, and may be untrustworthy. For example, operators mayconclude that an EOT device is accurate or “close enough” without usinga bright-line determination. Further, the use of forms and manualrecordation does not allow for an EOT transducer accuracy to becertified without an FRA inspector or other authority present.

SUMMARY OF THE INVENTION

Generally, it is an object of the present invention to provide a system,method, and apparatus for certifying a pressure calibration for anend-of-train device that overcomes some or all of the deficiencies ofthe prior art.

According to one preferred and non-limiting embodiment, provided is asystem for certifying an end-of-train device pressure calibration,comprising: a pressure calibration device configured to output aregulated air pressure; and an end-of-train device comprising: a brakepipe interface adapted to receive the regulated pressure from the aircalibration device; and a pressure measurement device programmed,configured, or adapted to obtain a measured pressure by measuring theregulated air pressure; wherein at least one of the pressure calibrationdevice and the end-of-train device comprises at least one controllerconfigured to determine a calibration certification result based atleast partially on a difference between the measured pressure and theregulated pressure.

A system for certifying an end-of-train device pressure calibration,comprising: (a) a pressure calibration device programmed, configured, oradapted to output a regulated pressure; and (b) an end-of-train devicecomprising: (i) a brake pipe interface adapted to receive the regulatedpressure from the pressure calibration device; and (ii) a pressuresensing device configured to obtain a measured pressure by measuring theregulated pressure, wherein at least one of the pressure calibrationdevice and the end-of-train device comprises at least one controllerprogrammed, configured, or adapted to determine a calibrationcertification result based at least partially on a difference betweenthe measured pressure and the regulated pressure.

According to another preferred and non-limiting embodiment, provided isa method for certifying an end-of-train device pressure calibration,comprising: applying a fixed pressure to a brake pipe interface of theend-of-train device; measuring the fixed pressure with the end-of-traindevice to determine a measured pressure; determining if the measuredpressure is within a predetermined range of the fixed pressure;generating pressure calibration certification data based at leastpartially on whether the measured pressure is within the predeterminedrange of the fixed pressure; and transmitting the pressure calibrationcertification data to at least one remote server.

According to a further preferred and non-limiting embodiment, providedis a computer program product for certifying an end-of-train devicepressure calibration on a mobile device including at least oneprocessor, the computer program product comprising at least onenon-transitory computer-readable medium including program instructionsthat, when executed by the at least one processor, cause the mobiledevice to: determine or receive an identification of the end-of-traindevice at least partially based on at least one of the following:scanning at least one visible indicia comprising identification data,receiving identification data from an input device, receiving aselection of an end-of-train device, receiving identifying data from anRFID transponder, receiving identifying data from a near-fieldcommunication device, or any combination thereof; determine or receive apressure calibration certification result based at least partially on afixed pressure applied to the end-of-train device and a measurement ofthe fixed pressure by the end-of-train device; and transmit, to at leastone remote server, the identification of the end-of-train device and thepressure calibration certification result.

According to another preferred and non-limiting embodiment, provided isan end-of-train device for certifying a brake pressure calibration,comprising: (a) a brake pipe interface adapted to receive a regulatedair pressure; (b) at least one pressure transducer programmed,configured, or adapted to measure the regulated air pressure; and (c) atleast one controller in communication with the at least one pressuretransducer, the at least one controller programmed, configured, oradapted to: (i) determine a variance between the regulated air pressureand a pressure measured by the at least one pressure transducer; (ii)determine a pressure calibration certification result based at leastpartially on the variance; and (iii) transmit, or cause another deviceto transmit, the pressure calibration certification result to at leastone remote server.

These and other features and characteristics of the present invention,as well as the methods of operation and functions of the relatedelements of structures and the combination of parts and economies ofmanufacture, will become more apparent upon consideration of thefollowing description and the appended claims with reference to theaccompanying drawings, all of which form a part of this specification,wherein like reference numerals designate corresponding parts in thevarious figures. It is to be expressly understood, however, that thedrawings are for the purpose of illustration and description only andare not intended as a definition of the limits of the invention. As usedin the specification and the claims, the singular form of “a”, “an”, and“the” include plural referents unless the context clearly dictatesotherwise.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates a schematic diagram of one embodiment of a system forcertifying a brake pressure calibration for an end-of-train deviceaccording to the principles of the present invention;

FIG. 2 illustrates a schematic diagram of another embodiment of a systemfor certifying a brake pressure calibration for an end-of-train deviceaccording to the principles of the present invention.

FIG. 3 illustrates a step-diagram for a system and method of a systemfor certifying a brake pressure calibration for an end-of-train deviceaccording to the principles of the present invention; and

FIG. 4 illustrates a step-diagram for a system and method of a systemfor certifying a brake pressure calibration for an end-of-train deviceaccording to the principles of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

For purposes of the description hereinafter, the teens “upper”, “lower”,“right”, “left”, “vertical”, “horizontal”, “top”, “bottom”, “lateral”,“longitudinal” and derivatives thereof shall relate to the invention asit is oriented in the drawing figures. However, it is to be understoodthat the invention may assume various alternative variations and stepsequences, except where expressly specified to the contrary. It is alsoto be understood that the specific devices and processes illustrated inthe attached drawings, and described in the following specification, aresimply exemplary embodiments of the invention. Hence, specificdimensions and other physical characteristics related to the embodimentsdisclosed herein are not to be considered as limiting.

As used herein, the terms “communication” and “communicate” refer to thereceipt, transmission, or transfer of one or more signals, messages,commands, or other type of data. For one unit or device to be incommunication with another unit or device means that the one unit ordevice is able to receive data from and/or transmit data to the otherunit or device. A communication may use a direct or indirect connection,and may be wired and/or wireless in nature. Additionally, two units ordevices may be in communication with each other even though the datatransmitted may be modified, processed, routed, etc., between the firstand second unit or device. It will be appreciated that numerousarrangements are possible. Any known electronic communication protocolsand/or algorithms may be used such as, for example, TCP/IP (includingHTTP and other protocols), WLAN (including 802.11 and other radiofrequency-based protocols and methods), analog transmissions, cellularnetworks (e.g., Global System for Mobile Communications (GSM) CodeDivision Multiple Access (CDMA), Long-Term Evolution (LTE), WorldwideInteroperability for Microwave Access (WiMAX), etc.), and/or the like.

In a preferred and non-limiting of the present invention, provided is asystem, method, and apparatus for certifying a brake pressurecalibration for an EOT device that includes a calibration device, orother regulated pressure source, and an EOT device including programmedsoftware and/or firmware. The EOT device measures a regulated pressureoutput by the calibration device and compares the measured pressure tothe amount of pressure actually output. The EOT device, including theEOT pressure transducer, is certified to be properly calibrated andaccurate if the measured pressure is within a predefined range from theregulated output pressure. The EOT device and/or the calibration devicethen transmits a certification result or other certification data to aremote server such as, but not limited to, a back office system, agovernmental agency server, a central dispatch authority, and/or thelike. The certification result indicates whether the EOT device haspassed or failed certification.

Referring now to FIG. 1, and according to a preferred and non-limitingembodiment, a system 1000 for certifying a brake pressure calibrationfor an EOT device 104 is shown. The system 1000 includes a calibrationdevice 102, an EOT device 104, an air source 106, and a back officesystem 108. The calibration device 102 includes a pressure regulator 110adapted to receive pressurized air from the air source 106 and toregulate the pressure according to a predetermined setting. It will beappreciated that, in addition to certifying an EOT device 104 with airpressure, the system 1000 may also be used with hydraulic/fluidic brakesystems, and use a fluid source and fluid pressure regulator.

Still referring to FIG. 1, a controller 112 of the calibration device102 is in communication with a pressure regulator 110, an input device126, a display device 124, a wireless communications device 116, aBluetooth adapter 118, and a serial interface 120. It will beappreciated that various other components and equivalents may be usedand that, in some non-limiting embodiments, the calibration device 102may have less, more, or different components than shown in FIG. 1.

With continued reference to FIG. 1, the wireless communications device116 may include, but is not limited to, any device or system configuredfor communication with a remote server 122 and/or the EOT device 104such as, for example, a cellular module or device, a wireless networkadapter that is configured to use a wireless internet or local areanetwork (LAN) connection, a mobile phone, and/or the like. The displaydevice 124 may include one or more display units configured to displaycharacters, text, images, and/or the like, or one or more displayadapters configured to communicate with external display units. Theinput device 126 may include a keyboard, a number pad, one or morebuttons, a touch screen device, and/or an adapter configured tocommunicate with external input devices.

Still referring to FIG. 1, the EOT device 104 may include variouscomponents such as, but not limited to, a brake pipe interface 130adapted to be connected to a brake pipe system of a train and thecalibration device 102, a pressure transducer 129, an EOT controller131, a display device 133, and a communications interface 137. Thecommunication interface 137 may include a serial interface, a wirelesscommunication device (e.g., a wireless model, Bluetooth adapter, and thelike), and/or other devices for communicating data. The pressuretransducer 129, communication interface 137, and display device 133 maybe in communication with the EOT controller 131. The pressure transducer129 may include any pressure sensing device capable of sensing and/ormeasuring gas or fluid pressure such as, but not limited to,piezoresistive strain gauges, capacitive sensors, piezoelectric sensors,optical sensors, potentiometric sensors, resonant sensors,electromagnetic sensors, and/or the like. The communication interface137 may be configured to communicate with the serial interface 120 orBluetooth adapter 118 of the calibration device 102. It will beappreciated that the EOT device 104 and calibration device 102 maycommunicate and exchange data in various other ways.

In one preferred and non-limiting embodiment, and with continuedreference to FIG. 1, a back office system 108 includes a remote server122, a certification database 109, and a certification printer 128. Itwill be appreciated that the remote server 122 may be in any locationand under the control of any entity such as, for example, a governmentalagency, a railroad company, a third-party, and/or the like. The remoteserver 122 includes one or more processors and is programmed,configured, or adapted to receive a pressure calibration certificationresult from the calibration device 102 and/or EOT device 104. In theexample shown in FIG. 1, the remote server 122 is in communication withthe wireless communications device 116 (e.g., wireless modem) of thecalibration device 102.

The certification printer 128 may be configured to print labelsindicating whether the EOT device 104 has passed or failedcertification. It will be appreciated that the certification printer 128may also be located anywhere, and does not necessarily need to beproximate to the remote server 122 and/or the back office system 108.For example, the certification printer 128 may be located in a testingstation, a repair center, a train yard, and/or the like, and be incommunication with the remote server 122, calibration device 102, and/orthe EOT device 104. If no certification printer 128 is available, thedisplay 124 on the calibration device 102 may indicate that a labelneeds to be manually printed. Further, the certification database 109may include one or more data structures that store pressure calibrationcertification data 101 for one or more EOT devices 104. Thecertification database 109 may also be located anywhere, and may be incommunication with the server 122, the calibration device 102, and/orthe EOT device 104. In the non-limiting example shown in FIG. 1, theremote server 122 stores the certification data 101 received from thecalibration device 102 in the certification database 109.

Still referring to FIG. 1, in a preferred and non-limiting embodiment,the EOT device may have various modes or states for testing, operation,and/or the like. A testing mode or state may include a calibrationcertification mode or state in which the EOT device 104, andparticularly the pressure transducer 129, is configured to receive aregulated air pressure through the brake pipe interface 130. In oneexample of operation, the EOT device 104 is removed from a train andtaken to a testing station, train yard, repair center, and/or the like.The EOT device 104 is then placed in calibration certification mode orstate by actuation or manipulation of a button or other input device 132on the EOT device 104, or through a command received from the backoffice system 108, remote server 122, and/or the calibration device 102.

Once the calibration device 102 and EOT device 104 have been connected,and the EOT device 104 is in a calibration certification mode or state,a fixed, regulated pressure is applied to the brake pipe interface 130by the calibration device 102. The pressure transducer 129 of the EOTdevice 104 measures the amount of pressure and communicates themeasurement data to the EOT controller 131. In a non-limitingembodiment, the calibration device 102 detects the connection of the EOTdevice 104 and initiates the calibration operation (i.e., regulatedoutput pressure) upon detection. The EOT controller 131 may also receivedata representing the actual pressure being applied (i.e., the pressureactually output by the pressure regulator) from, for example, thecalibration device 102 or another source through the communicationinterface 137.

After measuring the regulated pressure, the EOT controller 131 comparesthe measured pressure received from the pressure transducer 129 to theactual pressure being applied to the EOT device 104, and generatespressure calibration certification data 101 based at least partially onthe comparison. For example, if the pressure transducer 129 produces ameasurement that is within a predetermined range, percentage difference,or variance of the regulated pressure amount (e.g., +/−3 psi), thepressure calibration certification data 101 includes a certificationresult indicating that the EOT device 104 passed certification.Conversely, if the pressure transducer 129 produces a measurement thatis outside the predetermined range, percentage difference, or varianceof the regulated pressure amount, the certification result will indicatethat the EOT device 104 failed certification.

In a preferred and non-limiting embodiment, the pressure calibrationcertification data 101 may include, in addition to the certificationresult, the regulated pressure amount, the measured pressure from thepressure transducer 129, a date and/or time of the calibrationcertification, an identifier of the EOT device 104, an identifier of thecalibration device 102, an identification of one or more individualsconducting the calibration certification, a testing or inspectionlocation, an actual variance, a percentage variance, ranges thatindicate severity or lead to other specific actions, and/or other likeparameters and details. The pressure calibration certification data 101may be packetized for a particular communication protocol, or may be inthe form of any data structure such as, but not limited to, an array,vector, record or table, database, and/or the like.

Still referring to FIG. 1, it will be appreciated that various actionsand/or inputs may be used to initiate the pressure calibrationcertification of the EOT device 104, or to place the EOT device 104 in apressure calibration certification mode or state. For example, in onepreferred and non-limiting embodiment, an input device 132 of the EOTdevice 104, such as one or more buttons, touch screens, or the like, isused to initiate the process. In this example, an operator of the system1000 will apply a predefined and regulated pressure to the brake pipeinterface 130 of the EOT device 104 while the EOT device 104 is not inmotion and is removed from the train. The operator will then actuate ormanipulate the input device 132 until the display device 133 indicatesthat the EOT device 104 is in a calibration certification mode or state.For example, the display device 104 may show the letters “CERT” toindicate this mode or state. The operator will then actuate ormanipulate the input device 132 to begin the certification process.After the EOT device 104 measures the regulated pressure and comparesthe measured pressure to the fixed pressure amount received via thecommunication interface 137 or from elsewhere, the display device 133indicates the certification result (e.g., “PASS” or “FAIL”), andgenerates pressure calibration certification data 101 including thecertification result. The pressure calibration certification data 101 isthen transmitted by the EOT device 104 or the calibration device 102 tothe remote server 122.

In another preferred and non-limiting embodiment, and with continuedreference to FIG. 1, a menu on the display device 133 is used toinitiate the calibration certification process. For example, an operatorof the system 1000 may use the input device 132 to cycle through anoperational feature menu and select a pressure calibration certificationmode or state. The display device 133 may then display the currentpressure being measured by the pressure transducer 129. The input device132 may then be used to increment the displayed pressure amount (e.g.,in 1 psi increments or other units) until the display device 133 showsthe actual regulated pressure amount being applied to the brake pipeinterface 130. When the actual pressure being applied is displayed, theoperator will then wait a predetermined amount of time (e.g., fifteenseconds) and use the input device 132 to initiate the calibrationcertification process. At this point, the EOT controller 131 comparesthe currently displayed pressure amount with the measured pressure todetermine if the EOT device 104 passes or fails the certification. Thedisplay device 133 may then indicate the certification result (e.g.,“PASS” or “FAIL”), and the EOT controller 131 generates pressurecalibration certification data 101 including the result. As alreadydescribed, the pressure calibration certification data 101 may betransmitted by the EOT device 104 or the calibration device 102 to theremote server 122.

Referring now to FIG. 2, a preferred and non-limiting embodiment isshown of a system 1000 for certifying brake pressure calibration for anEOT device 104. In the embodiment depicted in FIG. 2, the EOT device 104includes a wireless communications device 135, such as a cellular moduleor device, a wireless network adapter that is configured to use awireless internet or local area network (LAN) connection, a mobile phoneconnection, and/or the like. The wireless communications device 135 isconfigured to communicate with a remote server 122, the calibrationdevice 102, and/or a mobile device 107. The EOT device 104 may alsocomprise visual indicia 201 that includes or contains identificationdata for the EOT device 104. The indicia 201 may include, but is notlimited to, a matrix barcode (e.g., a QR code or other two-dimensionalbarcode), a standard one-dimensional barcode, visual text capable ofbeing imaged and processed, and/or the like.

With continued reference to FIG. 2, and in a preferred and non-limitingembodiment, the mobile device 107 may include, but is not limited to, amobile phone, a laptop computer, a tablet computer, a Personal DigitalAssistant (PDA), and/or any other portable device capable of performingdata processing functions and communicating with other devices. Forexample, the mobile device 107 may include a general purpose smart phonecapable of running software applications. The mobile device 107 isconfigured with software and/or hardware to communicate with the remoteserver 122, the EOT device 104, and/or the calibration device 102. Thus,in various arrangements, the mobile device 107 may be used to initiateand/or implement the calibration certification process. The mobiledevice 107 includes a controller 141, such a central processing unit(CPU), a display device 139, a camera unit 145, and memory 143. Thedisplay device 139, in some embodiments, may be a touch screen that alsoservers as an input device. However, it will be appreciated that otherinput devices may be used with the mobile device 107.

In a preferred and non-limiting embodiment, and with continued referenceto FIG. 2, the operator of the system 1000 will apply a fixed, regulatedpressure to the brake pipe interface 130 of the EOT device using thecalibration device 102 or some other regulated pressure source. Themobile device 107 is configured to prompt the operator, through thedisplay device 133, to input an identification of the EOT device 104.For example, the camera unit 145 may be used to scan and/or image theindicia 201 on the EOT device 104, such that the controller 141 candetermine or extract identification data for the EOT device 104. If theindicia 201 comprises text, the mobile device 107 may use one or moretext recognition algorithms to determine the identification of the EOTdevice 104. If the indicia 201 comprises a barcode, the mobile device107 may extract the identification of the EOT device 104 using analgorithm that corresponds to the type of barcode. It will beappreciated that the identification of the EOT device 104 may also bemanually input into the mobile device 104 by the operator, received froma remote connection, selected from a menu, and/or the like.

Once the mobile device 107 has identified the EOT device 104, the mobiledevice 107 may prompt the operator to input the regulated pressure beingapplied to the EOT device 104. The regulated pressure may be manuallyinput or, in some embodiments, scanned and/or imaged using the cameraunit 145 from a display device on the calibration device 102 orelsewhere, wirelessly received from the remote server 122 or calibrationdevice 102, and/or selected from a menu displayed on the display device133 of the mobile device 107. The operator may then initiate themeasurement of the regulated pressure by the EOT device 107 through themobile device 107, which transmits a command to the EOT device 107,directly or via the remote server 122, or by manipulating an inputdevice 132 on the EOT device as described above.

Once the EOT device 107 initiates the calibration certification processand measures the regulated pressure, it compares the regulated pressureto the measured pressure. The mobile device 107 may obtain the measuredpressure in any number of ways such as, for example, from the EOT device104 or the calibration device 102, directly or via the remote server122, from the remote server 122, from operator input, or by any othermeans. After a determination is made whether the EOT device 104, haspassed certification, the mobile device 107, through the display device139, displays the certification result (e.g., “PASS” or “FAIL”). Themobile device 107, and more specifically the processor 141, may thengenerate pressure calibration certification data, including thecertification result, and transmit it to the remote server 122. Further,in one non-limiting embodiment, the EOT device 104 may determine thecertification result, as described above, and transmit it to the mobiledevice 107 or the remote server 122. In this embodiment, the mobiledevice 107 may be used to scan or image a display device 133 on the EOTdevice 104 to acquire the certification result.

In another preferred and non-limiting embodiment, and still referring toFIG. 2, the mobile device 107 may transmit a command to the remoteserver 122 to control the EOT device 104. For example, the mobile device107 may acquire the identification of the EOT device 104 as describedabove and transmit the identification to the remote server 122 thatincludes the regulated pressure being applied to the EOT device 104. Inresponse to this data, the remote server 122 may be configured totransmit a command to the EOT device 104 to initiate the calibrationcertification process. The EOT device 104 may then measure the regulatedpressure and compare the measured pressure with the actual regulatedpressure amount to determine the certification result.

Referring now to FIG. 3, a method for certifying a brake pressurecalibration is shown according to one preferred and non-limitingembodiment. Starting at step 301, a regulated or fixed pressure isapplied to a brake pipe interface 130 of an EOT device 104. At a nextstep 303, the regulated or fixed pressure is measured with a pressuretransducer 129 of the EOT device 104. At step 305, a determination ismade whether the measured pressure is within a predefined range of theregulated or fixed pressure applied. As discussed herein, thedetermination may be performed by a controller 131 of the EOT device104, by a mobile device 107, by a remote server 122, or by any otherdevice that is provided with the regulated pressure and the measuredpressure.

With continued reference to FIG. 3, if the measured pressure is withinthe predefined range, indicating that the variance between the twopressures is minor or insignificant, at step 307, a certification resultindicating successful certification (e.g., “PASS”) is displayed on theEOT device 104, the mobile device 107, or on any other display device.If the measured pressure is outside the predefined range, indicatingthat the variance between the two pressures is great enough to requirecalibration of the pressure transducer in the EOT device, at step 309 acertification resulting indicating an unsuccessful certification (e.g.,“FAIL”) is displayed on the EOT device 104, the mobile device 107, or onany other display device, at step 309. At step 311, pressure calibrationcertification data 101 is generated based at least partially on thecertification result. At step 313, the generated pressure calibrationcertification data 101 is transmitted to a remote server 122.

Referring now to FIG. 4, a method for certifying a brake pressurecalibration is shown according to another preferred and non-limitingembodiment. At a first step 401, a regulated or fixed pressure isapplied to a brake pipe interface 130 of an EOT device 104. At a nextstep 403, a mobile device 107 scans indicia 201 on the EOT device 104 toacquire identification information for the EOT device 104 and, at step405, the identification information is determined or otherwise extractedfrom the indicia 201. The mobile device 107 may scan the indicia usingan internal camera unit 145, as an example. It will be appreciated thatthe identification information may be acquired by the mobile device 107with a barcode reader, manual input, communication with the EOT device104, and/or the like. At a next step 407, the regulated pressure ismeasured by the EOT device 104. At step 409, the mobile device 107acquires the measured pressure from the EOT device 104 or user input.The mobile device 107 may acquire the measured pressure by scanning adisplay device 133 on the EOT device 104 that indicates the measuredpressure, by wireless or wired communication with the EOT device 104, bymanual input, and/or the like.

With continued reference to FIG. 4, at step 411, a determination is madewhether the measured pressure is within a predefined range of theregulated or fixed pressure applied to the EOT device 104. If themeasured pressure is within the predefined range, the mobile device 107displays an indication that the certification is successful (e.g.,“PASS”) at step 413. Likewise, if the measured pressure is outside thepredefined range, the mobile device 107 displays an indication that thecertification is unsuccessful (e.g., “FAIL”) at step 415. With eitherresult, the method proceeds to step 417 where pressure calibrationcertification data 101 is generated. At a final step 419, the pressurecalibration certification data 101 is transmitted to a remote server122.

In a preferred and non-limiting embodiment, and with reference to FIGS.1 and 2, an alert may be generated by the back office system 108, agovernment entity, or a remote server 122 to indicate that a pressurecalibration certification is due for a particular EOT device 104. Forexample, the EOT device 104 may receive an alert from the back officesystem 108 that causes the EOT device 104 to display, on the displaydevice 133, a warning message or alert that the pressure calibrationcertification is due or expired. The warning message or alert may bedisplayed at any time, or may be displayed when the EOT device 104 isinstalled on a train or service bench. The warning message or alert maybe generated automatically at predetermined intervals, or upon requestof another party or entity. The certification database 109 may storeanalytical data that indicates, for various EOT devices 104, whether aparticular EOT device 104 is past due for calibration, or is properlycalibrated.

In a further preferred and non-limiting embodiment, existing EOT devices104 may be provided with an external serial-to-Bluetooth adapter toallow for interaction with mobile devices 107. In this manner, a mobiledevice 107 may be used to receive the measured pressure andidentification of the EOT device 104, as examples, determine thecertification result, and transmit the certification result and/orpressure calibration certification data 101 to the remote server 122. Itwill be appreciated that various other wireless communication protocolsmay be used such as, for example, shared wireless networks, infraredsignals, near-field communication, and/or the like.

In a preferred and non-limiting embodiment, and with reference to FIGS.1 and 2, the remote server 122 may be configured to determine what EOTdevices 104 require certification and/or calibration. For example, whenan EOT device 104 is certified, the date and/or time of thatcertification may be stored in the certification database 109 and beused to determine or predict a date that a subsequent certification isdue (e.g., at annual intervals). When the scheduled date forcertification occurs, the remote server 122 may identify the location ofthe EOT device 104 and transmit an alert that an EOT device 104 is duefor certification. The alert may be transmitted to, for example, the EOTdevice 104, an onboard locomotive computer, the calibration device 102,a mobile device 107, an email address, and/or the like. Further, theremote server 122 may determine that a particular EOT device 104 is duefor certification and/or calibration at an earlier date based on thepressure calibration certification data 101. For example, if thepressure calibration certification data 101 indicates that the EOTdevice 104 has passed certification, but that the measured pressure wasclose to failing certification (e.g., 2 psi over or under if thecertification threshold is 3 psi), the remote server 122 may send analert earlier.

In non-limiting embodiments, the remote server 122 may analyze trends inthe measured pressure amounts and variances to predict a time that theEOT device 104 should be calibrated. The trends may be analyzed usingthe drift amount of the pressure transducer 129 measurements. Byanalyzing a gradual degradation that results in a growing variancebetween measured pressure and actual pressure, an accurate prediction ispossible of when the EOT device 104 will require calibration. It will beappreciated that such a prediction may also be at least partially basedon temperature, atmospheric pressure, and other factors.

In a further preferred and non-limiting embodiment, the remote server122 and/or back office system 108 may allow for governmental entities,such as the FRA, to inspect the certification database 109 and/or otherinstances of pressure calibration certification data 101. This allowsthe FRA or other entities to obtain calibration and/or certificationevidence without requiring on-site inspection of an EOT device 104.Further, the pressure calibration certification data 101 may betransmitted directly to the FRA or other entities.

In non-limiting embodiments, a method to certify a brake pressurecalibration for an end-of-train device may be performed by at least onenon-transitory computer-readable medium including program instructionsthat, when executed by at least one processor, cause one or more devicesto perform the steps. With the sole exception of transitory propagatingsignals, a non-transitory computer-readable medium may include anymedium capable of storing data such as, but not limited to,random-access memory (RAM) and other forms of memory, hard drives,compact and floppy discs, and the like.

Although the invention has been described in detail for the purpose ofillustration based on what is currently considered to be the mostpractical and preferred embodiments, it is to be understood that suchdetail is solely for that purpose and that the invention is not limitedto the disclosed embodiments, but, on the contrary, is intended to covermodifications and equivalent arrangements that are within the spirit andscope of the appended claims. For example, it is to be understood thatthe present invention contemplates that, to the extent possible, one ormore features of any embodiment can be combined with one or morefeatures of any other embodiment.

What is claimed is:
 1. A method for certifying an end-of-train devicepressure calibration, comprising: applying a fixed pressure to a brakepipe interface of the end-of-train device with an automated calibrationdevice while the end-of-train device is removed from a train; measuringthe fixed pressure with the end-of-train device to determine a measuredpressure; determining if the measured pressure is within a predeterminedrange of the fixed pressure; generating pressure calibrationcertification data based at least partially on whether the measuredpressure is within the predetermined range of the fixed pressure; andtransmitting the pressure calibration certification data to at least oneremote server.
 2. The method of claim 1, wherein the automatedcalibration device transmits the pressure calibration certification datato the at least one remote server.
 3. The method of claim 1, wherein theautomated calibration device comprises at least one of the following: adisplay device, an adapter for a display device, a user input device, anadapter for a user input device, a Bluetooth adapter, a serialinterface, or any combination thereof.
 4. The method of claim 1, whereinthe pressure calibration certification data comprises a pressurecalibration certification result, and wherein the pressure calibrationcertification result indicates that the end-of-train device passed orfailed certification.
 5. The method of claim 4, wherein the pressurecalibration certification data further comprises at least one of thefollowing: an identifier of the end-of-train device, a date, a location,the measured pressure, the fixed pressure, or any combination thereof.6. The method of claim 1, wherein the end-of-train device comprisesmachine-readable indicia or device comprising data identifying theend-of-train device, and wherein the end-of-train device comprises atleast one display, the method further comprising: scanning themachine-readable indicia or device with a mobile device; and scanningthe at least one display with the mobile device after the end-of-traindevice has measured the fixed pressure and displays the measuredpressure on the at least one display.
 7. The method of claim 6, whereinthe mobile device determines if the measured pressure is within thepredetermined range, wherein the pressure calibration certification datais generated by the mobile device, and wherein the mobile devicetransmits the pressure calibration certification data to the at leastone remote server.
 8. The method of claim 6, further comprisinginputting, into the mobile device, a value representing the fixedpressure.
 9. The method of claim 1, further comprising transmitting,from a mobile device to the at least one remote server, data configuredto cause the at least one remote server to transmit, to the end-of-traindevice, data configured to cause the end-of-train device to enter acertification mode.
 10. The method of claim 9, further comprisingreceiving, on the mobile device, the fixed pressure amount from a sourceof the fixed pressure.
 11. The method of claim 1, further comprisingreceiving, from the at least one remote server, data configured todisplay a warning message or alert on the end-of-train device when acalibration certification is due or expired.
 12. A computer programproduct for certifying an end-of-train device pressure calibration on amobile device including at least one processor, the computer programproduct comprising at least one non-transitory computer-readable mediumincluding program instructions that, when executed by the at least oneprocessor, cause the mobile device to: determine or receive anidentification of the end-of-train device at least partially based onscanning at least one machine-readable indicia or device comprisingidentification data; determine or receive a pressure calibrationcertification result based at least partially on a fixed pressureapplied to the end-of-train device and a measurement of the fixedpressure by the end-of-train device; and transmit, to at least oneremote server, the identification of the end-of-train device and thepressure calibration certification result.
 13. The computer programproduct of claim 12, wherein the program instructions, when executed bythe at least one processor, further cause the mobile device to: acquirethe fixed pressure applied to the end-of-train device; and acquire, fromthe end-of-train device, the measurement of the fixed pressure.
 14. Thecomputer program product of claim 12, wherein the program instructions,when executed by the at least one processor, further cause the mobiledevice to: capture at least one image of at least one display on theend-of-train device by a camera unit of the mobile device; and acquireat least one of the fixed pressure amount and the measurement byprocessing the at least one image of at least one display on theend-of-train device.
 15. The computer program product of claim 12,wherein the program instructions, when executed by the at least oneprocessor, further cause the mobile device to: acquire the fixedpressure amount from a pressure calibration device that outputs thefixed pressure.
 16. The computer program product of claim 12, whereinthe program instructions, when executed by the at least one processor,further cause the mobile device to transmit, to the at least one remoteserver or the end-of-train device, data configured to cause theend-of-train device to initiate the measurement of the fixed pressure.17. The computer program product of claim 12, wherein the programinstructions, when executed by the at least one processor, further causethe mobile device to: wirelessly communicate with at least one of theend-of-train device and a pressure calibration device that outputs thefixed pressure.
 18. The computer program product of claim 12, whereinthe program instructions, when executed by the at least one processor,further cause the mobile device to: receive the pressure calibrationcertification from at least one of the end-of-train device and apressure calibration device that outputs the fixed pressure.
 19. Asystem for certifying an end-of-train device pressure calibration,comprising: (a) a pressure calibration device configured to output aregulated pressure; (b) an end-of-train device comprising: (i) a brakepipe interface adapted to receive the regulated pressure from thepressure calibration device; (ii) a pressure sensing device configuredto obtain a measured pressure by measuring the regulated pressure; and(iii) at least one machine-readable indicia or device, the at least onemachine-readable indicia or device comprising identification data forthe end-of-train device; and (c) at least one mobile device configuredto read or scan the at least one machine-readable indicia or device todetermine the identification data, wherein at least one of the pressurecalibration device and the end-of-train device comprises at least onecontroller configured to determine a calibration certification resultbased at least partially on a difference between the measured pressureand the regulated pressure.